KR20000003381A - Method and device for driving a plasma display panel - Google Patents

Abstract

PURPOSE: A plasma display panel driving method and a method using the same are provided to suppress an outline noise of an image displayed on the plasma display panel and to reduce maximum power consumption. CONSTITUTION: The plasma display panel driving method for displaying an image signal of multi gray scale constituting a first frame as plural sub-fields that the relative rate of a brightness are different from each other, comprises arranging sub-frames differently from each other according to a distribution of logic values of image signals of the first frame.

Description

Method of Driving Plasma Display Panel and Apparatusd

The present invention provides a halftone image such that a pseudo contour noise pattern generated by driving a plasma display panel (hereinafter referred to as "PDP") that expresses the gray level of an image by pulse width modulation (PWM) is not displayed. A display method and apparatus are provided.

Recently, a plasma display panel (hereinafter referred to as "PDP") has attracted attention as a thin and lightweight display device. In the case of displaying an intermediate image of a video signal (e.g., a television signal) with this PDP, a modulation method is generally used in which the number of emission is proportional to the video signal. Specifically, the video signal is digitized and each frame period is divided into subfield periods corresponding to the number of bits of the digitized video data. In each subfield period, gradation display is performed by the number of times of light emission in proportion to the weight of digital video data.

For example, one frame display period (hereinafter referred to as " unit frame period ") in each pixel when an intermediate tone image is displayed in 8 bits, i.e., 256 gray levels, 1F (e.g., 1/30 second = about 33 msec) ) Is divided into eight subfield periods SF1 to SF8 as shown in FIG. 1, and each subfield period SF1 to SF8 is further divided into an erasing period IP, an address period AP, and a display period SP. The display period SP is divided into 1: 2: 4: 8:... Give a weighting ratio of: 128. The erase period IP and the address period AP are the same in each subfield period (for example, the duration of the IP and the AP is 1.5 ms). In the PDP driving method, the display order of the subfield periods corresponding to each bit is in a constant order as in the example of SF1, SF2, SF3, SF4, SF5, SF6, SF7, SF8. Since the subfield periods are arranged in a certain order, the display area and the non-display area are mixed as shown in FIG. 2 in one frame period according to the logic value of the pixel. In other words, the display period and the non-display period are distributed in various forms in one frame period according to the logic value of the pixel.

As described above, in the conventional halftone image display method, since the display order of the subfield periods SF1 to SF8 becomes constant, a fake image is generated at a pattern boundary in an image in which a constant pattern is moving, and the fake image is a human image. As in the face, it becomes the upper contour part which occurs in the part where the brightness changes gradually, or a sudden change in the brightness occurs in the part where the change in the brightness is gentle. In other words, contour noise is generated in the display image displayed by the conventional halftone image display method. In addition, when the display panel is a color, the color generally changes. The dispersion of the display period and the non-display period in one frame period adds to the generation of contour noise and increases power consumption. As a result, in the conventional halftone display method, the display image quality is remarkably degraded. In addition, the power consumption in the PDP is increased and the maximum power consumption difference is large because the post-address sustains the full screen simultaneously.

Accordingly, it is an object of the present invention to provide a PDP driving method and apparatus suitable for suppressing contour noise in an image displayed on a PDP panel.

It is another object of the present invention to provide a PDP driving method and apparatus suitable for suppressing contour noise in an image displayed on a PDP panel, reducing power consumption and reducing maximum power consumption.

1 is a diagram showing a driving mode of a video signal according to a conventional PDP driving method.

Fig. 2 is a diagram showing a mode in which a panel is driven by a conventional PDP driving method.

3 is a diagram schematically showing a PDP driving apparatus according to an embodiment of the present invention;

Fig. 4 is a diagram showing an example of driving of a video signal by the PDP driving apparatus of the present invention.

Fig. 5 is a diagram showing a mode in which a PDP is driven by the PDP driving apparatus of the present invention.

<Description of the reference numerals for the main parts of the drawings>

10: PDP 12: frame memory

14 data driver 16 scan data generator

18: sustain waveform generator 20: sustain drive unit

22: controller

In order to achieve the above object, in the PDP driving method according to the present invention, in order to display a multi-gradation video signal, one frame is composed of a plurality of subfields having different relative ratios of luminance, and one frame is divided into a display period and a non-display period. The subfields are arranged differently according to the distribution of logical values of the video signal for one frame.

In the PDP driving method according to the present invention, in order to display a multi-gradation video signal, one frame including a plurality of subfields having different relative ratios of luminance includes the remaining subfields except the subfield having the smallest relative ratio of luminance. It will be included.

The PDP driving apparatus according to the present invention comprises a signal input means for inputting a video signal, an address drive means for driving address electrodes on the plasma display panel by the video signal from the signal input means, and between the signal input means and the address drive means. A frame memory for temporarily storing an image signal, sustain driving means for driving sustain electrodes on a plasma display panel, one frame having a plurality of subfields having different relative ratios of luminance, and displaying a frame And control means for controlling the sustain drive means in the form of a period and a non-display period.

The PDP driving apparatus according to the present invention comprises a signal input means for inputting a video signal, an address drive means for driving address electrodes on the plasma display panel by the video signal from the signal input means, and between the signal input means and the address drive means. A frame memory for temporarily storing an image signal, a sustain driving means for driving sustain electrodes on the plasma display panel in a frame composed of a plurality of subfields having different relative ratios of luminance, and included in the frame And a control means for controlling the sustain driving means so that the one frame is constituted by the remaining subfields except the subfield having the smallest relative ratio of luminance among the subfields.

Other objects and advantages of the present invention in addition to the above objects will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 3 to 4.

Referring to FIG. 3, the frame memory 12 and the data driver 14 connected in series between the input line 11 and the PDP 10 and the scan data generator 16 and the PDP 10 are connected in series. A PDP driving apparatus according to an exemplary embodiment of the present invention having a sustain waveform generator 18 and a sustain driver 20 is shown. The frame memory 12 connected to the input line 11 is supplied with image data including n (eg, 8) bits of pixel signals. The frame memory 11 transmits the image data from the input line 11 to the data driver 14 by one frame. At this time, in the image data transmitted from the frame memory 12 to the data driver 14, pixel signals of a single bit corresponding to the weight of the subfield are continuous. For example, when the PDP 10 is driven during a sub-field period having a weight of 128, the MSB bit pixel signals are continuous in the image data supplied to the data driver 14. In order to perform this function, the frame memory 12 is configured as a single port memory for storing two frames of image data or a dual port memory suitable for storing one frame of image data. The data driver 14 drives the address electrodes (not shown) on the PDP 10 by the image data from the frame memory 12.

The scan data generator 16 generates various frame scan patterns according to a logic value distribution of the pixel signals of the frames stored in the frame memory 12. The frame scan pattern output from the scan data generator 16 changes in units of frames. Alternatively, the scan data generator 16 may output a frame scan pattern that changes in units of lines. In this case, the frame scan pattern is determined according to the logical value distribution of the pixel signals for the line. In order to generate such a frame pattern, the scan data generator 16 stores frame scan patterns according to a logical value distribution of pixel signals of frames or lines. In each of the frame scan patterns stored in the scan data generator 16, the subfields SF2 to SF8 are positioned irrespective of the weight of the period assigned to them as shown in FIG. As such, the subfields SF2 to SF8 are arranged irrespective of the weight of their period so that the contour noise is reduced. Referring to FIG. 4, all of the frame scan patterns do not include the lowest subfield (hereinafter, referred to as “first subfield”) or SF1. The first subfield SF1 has the shortest weight and corresponds to the least significant bit of the pixel signal and is known to have the greatest influence on the generation of contour noise. By eliminating this lowest subfield (hereinafter referred to as "first subfield") and SF1, the contour noise is significantly reduced in the image displayed by the PDP 10. In addition, in the frame scan pattern, the most significant subfield (hereinafter referred to as "the eighth subfield") and SF8 having the longest weight of the period are arranged in a divided form. In other words, the highest subfield SF8 having a period weight of 128 is divided into a pre subfield SF8a and a post subfield SF8b each having a period weight of 64, respectively. Among them, the pre subfield SF8a is arranged between the fourth and sixth subfields SF4 and SF6, and the post subfield SF8b is arranged between the fifth and third subfields SF5 and SF3. do. Further, as shown in Fig. 4, the positions of each of the subfields SF2 to SF8 arranged in the order of SF2, SF4, SF8a, SF6, SF7, SF5, SF8b and SF3 in one frame period are determined by the logical value of the pixel signals. It changes randomly according to the distribution. As the subfields SF2 to SF8 change randomly, the frame scan pattern causes one frame period to be divided into a display period and a non-display period as shown in FIG. Accordingly, the period during which the PDP panel is driven and the period during which the PDP panel is not driven appear once in one frame period. As a result, power consumption is significantly reduced in the PDP driving apparatus according to the embodiment of the present invention. The scan data generator 16 also controls the reading of the image data in the frame memory 12. In detail, the scan data generator 16 designates the storage areas of the frame memory 12 such that the image data read from the frame memory 12 corresponds to the frame scan pattern supplied to the sustain waveform generator 18. . Accordingly, in the frame memory 12, pixel signals of bits corresponding to each of the subfields SF are read out one frame or one line. A sustain drive signal is generated in the sustain waveform generator 18 which inputs the frame scan pattern from the scan data generator 16. This sustain drive signal has a waveform that varies depending on the frame scan pattern. In addition, the sustain driver 20 drives the sustain electrodes on the PDP 10 by the sustain drive signal from the sustain waveform generator 18.

In addition, the PDP driving apparatus according to the embodiment of the present invention includes a controller 22 which is commonly connected to the frame memory 12 and the scan data generator 16. The controller 22 controls the write operation of the frame memory 12 and detects a distribution of logic values of pixel signals of one frame stored in the frame memory 12. In addition, the controller 22 supplies the distribution of the logical value of the detected pixel signals to the scan data generator 16 so that the frame scan pattern output from the scan data generator 16 varies depending on the frame. In addition, the controller 22 controls the read timing of the frame memory 12 according to the frame scan pattern output from the scan data generator 16. Alternatively, the controller 22 may detect a distribution of logic values of pixel signals for each line among the image data stored in the frame memory 12. In this case, the scan data generator 16 outputs frame scan patterns that vary according to the lines on the PDP 10. Accordingly, the lines on the PDP 10 are driven by frame scan patterns in which subfield periods are arranged differently.

As described above, in the PDP driving apparatus according to the embodiment of the present invention, the subfields are arranged differently according to the distribution of the logical values of the pixel signals so that one frame period is divided into the display period and the non-display period. In addition, in the PDP driving apparatus according to the embodiment of the present invention, the display period is compressed by distributing and arranging arbitrary subfields, for example, the most significant subfield period for the pixel signal of the most significant bit, into two divided forms. As a result, generation of contour noise in the image displayed on the PDP is suppressed, and power required for driving the PDP is reduced. In addition, in the PDP driving apparatus according to the embodiment of the present invention, the contour noise in the image displayed on the PDP is further reduced by removing the lowest subfield period for the least significant bit of the pixel signals.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (12)

A plasma display panel driving method for displaying a multi-gradation video signal constituting one frame with a plurality of subfields having different relative ratios of luminance, the method comprising: And the subfields are arranged differently according to a distribution of logical values of the video signal for the one frame such that the one frame is divided into a display period and a non-display period. The method of claim 1, And a subfield having the largest relative ratio of luminance among the subfields is arranged in the one frame in a divided form. A plasma display panel driving method for displaying a multi-gradation video signal constituting one frame with a plurality of subfields having different relative ratios of luminance, the method comprising: And combining the one frame into the remaining subfields except the subfield having the smallest relative ratio of luminance among the subfields. The method of claim 3, wherein And subfields included in the first frame are arranged differently according to a distribution of logical values of the video signal for the one frame so that the one frame is divided into a display period and a non-display period. The method of claim 4, wherein And a subfield having the largest relative ratio of luminance among the subfields is arranged in a divided form. Signal input means for inputting a video signal; Address driving means for driving address electrodes on the plasma display panel by the image signal from the signal input means; A frame memory installed between the signal input means and the address driving means for temporarily storing a video signal; Sustain driving means for driving the sustain electrodes on the plasma display panel; And a control means for controlling the sustain driving means in such a manner that one frame is composed of a plurality of subfields having different relative ratios of luminance and the frame is divided into a display period and a non-display period. Panel drive. The method of claim 6, And the control means controls the sustain driving means such that a plurality of subfields are arranged differently according to a distribution of logical values of an image signal for one frame stored in the frame memory. The method of claim 6, And the control means is arranged such that the subfield having the largest relative ratio of luminance among the subfields is arranged in the one frame in a divided form. Signal input means for inputting a video signal; Address driving means for driving address electrodes on the plasma display panel by the image signal from the signal input means; A frame memory installed between the signal input means and the address driving means for temporarily storing a video signal; Sustain driving means for driving the sustain electrodes on the plasma display panel in a form in which one frame includes a plurality of subfields having different relative ratios of luminance; And a control means for controlling the sustain driving means to configure the one frame by the remaining subfields except the subfield having the smallest relative ratio of luminance among the subfields included in the frame. Panel drive. The method of claim 9, And the control means controls the sustain driving means so that the one frame is divided into a display period and a non-display period. The method of claim 9, The control means controls the sustain driving means so that the subfields included in the one frame are arranged differently according to the distribution of the logical value of the video signal for the one frame stored in the frame memory. Panel drive. The method of claim 9, And the control means causes the subfields having the largest relative ratio of luminance among the subfields included in the one frame to be arranged in the first frame in a divided form.